The present invention relates to trucks for refuse packing, and especially to truck bodies adapted to pack recyclable refuse.
Some communities desire the separate recycling of three kinds of materials: metals, paper goods, and organics. Although truck bodies are known for providing three compartments for receiving, packing, and ejecting three types of recyclables, such bodies have one sump, one sweep blade and one pack blade for each compartment, with two compartments loaded from the rear of the body and one compartment loaded from the sidewalk side of the body. This configuration has two main disadvantages. First, three sets of power and actuation components are required, with the resultant high cost of components and encroachments on available space for the packing compartments. Second, curbs, poles, signs and other roadside obstacles can inconvenience and endanger the collection worker at the side sump.
The present invention is generally directed to a multi-compartment, sweeper-type rear loading refuse packer for a truck body, wherein a single pack blade cooperates with a multi-section sweep blade.
The sweep blade can be unitary, with multiple sections connected together and driven as a unit or the sweep blades can be segmented, with each driven individually.
This enables the collection worker to separately load all three types of recyclables at the rear of the truck, and reduces the number and space occupied by the power and actuation components.
In a three compartment configuration, the sweep blade has two spaced apart slots which cooperate with a respective two collection sump dividers that extend to the openings of the compartments. This defines three collection sumps and three channels leading into a respective three longitudinal packing compartments. With a unitary sweep blade option, the blade comprises opposed top and bottom continuous edges of greater lengths than opposed lateral edges, with an optional curvature from top to bottom, and with laterally spaced slots extending at least halfway from the bottom edge toward but not reaching the top edge. With a segmented sweep blade, the slots extend the full blade height from top to bottom. The sweep blade spans all the collection sumps from above and the two vertical slots are laterally spaced at a distance corresponding to the lateral space between the compartment dividing walls, thereby defining three blade sections drivable toward through the collection sumps toward the loading floors of the compartments.
Yet another embodiment is directed to a rear load refuse body comprising three packer compartments extending longitudinally from the front toward the back of the body; three laterally divided collection sumps at the lower back of the body, for receiving a respective three loads of segregated refuse; and a sweep blade extending laterally across all the sumps, with three sections corresponding to the three collection sumps. The sweep blade sections are movable respectively within each sump. A first drive system is provided for sweeping the entire sweep blade whereby each sweep blade section sweeps through each respective collection sump and thereby transports collected refuse toward the floor of a respective compartment. A single pack blade is coupled to the sweep blade and driven by a second drive system. As the pack blade is displaced obliquely, it lifts the sweep blade obliquely such that the sweep blade and pack blade push the collected refuse into respective compartments, against compaction faces carried on respective ejection cylinders in the compartments.
In an ideal three compartment system, cost and space are minimized when the sweep blade is unitary with three sections and the first drive system for the sweep blade has only two hydraulic cylinders, but space savings are still achieved even when the sweep blade has three segments driven by a respective three cylinders. In both embodiments, space savings are achieved by the use of a single pack blade, with the associated second drive system consisting of two hydraulic cylinders.
As used herein, the terms “multiple” and “multi” mean “at least two”, and description of a compaction unit having multiple collection sumps or sweep blade having multiple sections according to the invention does not necessarily preclude the compaction unit from including an additional sweep blade and associated collection sump. The main advantage of the present invention is that for a compaction unit having a particular number of collection sumps with associated sweep blade sections, efficient operation can be achieved with fewer pack blades than the number of sweep blade sections. For example, in a hybrid three compartment packer, the compaction unit can have one conventional sump, sweep blade with dedicated drive, and pack blade with dedicated drive, in side-by-side combination with two other sumps having a two-section sweep blade and single pack blade according to one aspect of the invention. The inventive two-section sweep blade could be unitary or segmented, have either one or two associated drives, but with a single pack blade. Instead of the drive systems requiring six drives, only four or five drives would be required. This hybrid configuration would fall within the open-ended recitation of a multi-compartment, sweeper-type rear loading refuse compaction unit for a truck body, comprising a single pack blade pivotally connected to a multi-section sweep blade.
Another problem arises when the compaction unit is raised open for refuse ejection of the three compartments. There is a tendency for refuse in all three compartments to start dropping. This is undesirable, as the type of refuse in each compartment is different and must be offloaded separately. According to another improvement, this problem is solved by providing a sloped lower back end to the refuse compartments and two anti-spill plates cooperating with the sloped back end for blocking the lower portion of the outer two compartments. The two anti-spill plates hold the contents within the outside compartments, thus enabling the center compartment to be ejected first. Once the center compartment is unloaded, each of the outside compartments is uncovered in turn by lowering the respective anti-spill plate.
In a further feature to prevent spillage through the rear opening of one or more compartments, each having upper region and a lower regions, the anti-spill plate associated with a sump is displaceable to cover the lower region of the opening, and a seal plate is mounted on the body in vertical opposition to each anti-spill plate, to selectively cover the upper region of the opening. In the way the anti-spill plate and the seal plate confront and close the opening of the associated refuse compartment when the compaction unit is pivoted to the ejection position.
The anti-spill plates and seal plates can be advantageously used with any type of seep and pack blade configuration. Thus, an aspect of the invention is directed to a refuse truck having a refuse receiving body including a front, a back, a top, and a bottom, with at least one refuse compartment with an opening accessible at the back of the body, comprising; an anti-spill plate supported by the body, and rotatable between an open position away from a lower region of the opening and a closed position against the lower region of the opening; and a seal plate supported by the body, and rotatable between an open position away from an upper region of the opening and a closed position against the upper region of the opening.
The inventive principles described herein can be readily implemented in two, three, four or more compartment configurations.
A first drive system is provided for pivoting each sweep blade section through each respective collection sump toward the floor of a respective the compartment (as shown in step 3 of
It can be appreciated that the pack blade has a lower edge that is pivotally connected along a transverse axis to an upper edge of the sweep blade; a first drive system pivots the sweep blade around the transverse axis, over an included angle that follows the shape of the sump; and a second drive system displaces the pack blade with sweep blade obliquely from the sump to the floors of the compartments.
As also shown in
The pack blade 152 extends laterally across the body above the sweeper blade 132, for oblique movement toward and away from the compartments. Pack blade cylinders 154a, 154b are shown mounted inside the body or frame for this purpose and connect to an additional cross brace 156, but the pack blades can alternatively be mounted outside the frame. Braces 158a, 158b are also provided. The lower edge 160 of the packer blade is in essence pivotally connected along a transverse axis to the upper edge 138 of the sweep blade for cooperative movement as described with respect to
Refuse in each compartment 114, 116, 118 is packed as the pack blade 30, 152 and sweep blade 32 as sectioned per 140, 142, 144, push the refuse into the openings 40 at the rear of the compartments. The refuse is pushed against packing faces 162, 164, 166 on the ejection cylinders 168, 170, 172. The cylinders retract as the compartments fill with packed refuse. When the truck is full, the entire compaction unit 24 (
Regardless of the number of compartments, sweep blade sections or segments, and sweep blade cylinders, only one pack blade is required, which can be actuated by only two internal or external cylinders.
When the compaction unit 24 is raised open for refuse ejection of the three compartments, there is a tendency for all three compartments to start spilling refuse. This is undesirable, as the type of refuse in each compartment is different and must be offloaded separately.
When the truck is full and ready to unload (
Once the center compartment is unloaded, each of the outside compartments is uncovered in turn by lowering the respective anti-spill plate.
It should be understood that the anti-spill plates are inside the respective sumps, below the sweep path of the sweep blades when the compaction unit is in the collection position. Each anti-spill plate is displaceable out of the sump for confronting the bottom of the associated refuse compartment when the compaction unit is pivoted to the ejection position.
The back of the body is shown with angled profile 224 with an edge that can be fitted with resilient seals such as outer seal 226 and inner seal 228. A straight (or as shown) correspondingly angled 230 seal plate 208 is pivotally connected with a drive system at the top, or near the roofline of the body. The outer seal 226 can be a strip, ridge, ledge or shaped plate fixed to the body whereas each of the two inner seals 228 would generally be a strip covering the two edges of the central compartment walls. The seal plate 208 extends over the upper region of the opening, down to the tops 232, 232′ of the vertical outer body support and vertical portion of the internal divider wall, which defines the lower region.
When the compaction unit is lifted, each lateral compartment thus has a rear opening with upper and lower regions. The upper region is subject to closure with the sealing plates and the lower region is subject to closure with the anti-spill plates, thereby preventing spillage while the central or other lateral compartment is being unloaded. As shown in
In a three-compartment system, when the compartments are to be emptied, generally the central compartment is emptied first, while the lateral compartments are both sealed with the closed seal plates and closed anti-spill plates, as shown in to
As an alternative, the seal plates could be simply hinged, with each being heavy enough to stay closed and only open as a result of the pressure of the contents being pushed out the back end by the hydraulic ram.
It should be understood that a similar need for preventing spillage arises in a two-compartment or even four-compartment system. The anti-spill plates and sealing plates as described above can be readily implemented into any refuse body having multiple (at least two) compartments.
The present application claims the benefit of the filing date under 35 U.S.C. § 119(e) of U.S. Provisional Application No. 62/161,996 filed May 15, 2015 for “Three Compartment Rear Load Packer” and U.S. Provisional Application No. 62/174,748 filed Jun. 12, 2015 for “Three Compartment Refuse Packer with Anti-Spill Plates”, the disclosures of which are hereby incorporated by reference.
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/US2016/032432 | 5/13/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2016/187031 | 11/24/2016 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3878949 | Colin | Apr 1975 | A |
3961717 | Sabine | Jun 1976 | A |
4057154 | Neufeldt | Nov 1977 | A |
4460307 | Durant | Jul 1984 | A |
5123801 | O'Daniel | Jun 1992 | A |
7118320 | Tomassoni | Oct 2006 | B2 |
20050220593 | MacPherson | Oct 2005 | A1 |
20060045700 | Siebers | Mar 2006 | A1 |
20140348621 | Brisson | Nov 2014 | A1 |
Entry |
---|
“Greener Advantage”, Retrieved from http://www.roystrom.com/print/94, 2017, 1 page. |
Number | Date | Country | |
---|---|---|---|
20180155125 A1 | Jun 2018 | US |
Number | Date | Country | |
---|---|---|---|
62161996 | May 2015 | US | |
62174748 | Jun 2015 | US |